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The Armadillo Vault’s hundreds of limestone slabs are held together without glue

The ability of the Armadillo Vault to stand strong without any glue is nothing less than an ingenious feat of engineering. ETH Zurich designed the massive structure out of limestone slabs for the Venice Biennale 2016, showing how any material can become architecturally versatile with detailed design and a bit of finesse.

ETH Zurich’s Block Research Group worked in collaboration with engineering firm Ochsendorf DeJong & Block and masonry specialist The Escobedo Group to bring the structure to life using expertly designed compression techniques. 399 limestone slabs were brought together after mapping out the technique on RhinoVAULT, a design plugin licensed by the group. Philippe Block and Tom Van Mele of the research group said, “Without any glue or mortar, with perfectly dry connections, this is really a milestone for stone engineering.”

The Armadillo Vault spans 16 meters (about 20 feet), yet some sections are only as thick as five centimeters. Proportionally, the structure is half the thickness of an eggshell and remarkably strong. Each slab of limestone was left unfinished on the bottom side for time’s sake, creating an exterior resembling an armadillo shell and an underbelly of textured stripes. The intentional choice of finicky limestone demonstrates how the “relationship between geometry and forces” can be achieved with precision and respect for the materials.

Once the Venice Biennale ends, the Armadillo Vault will be moved to a different location. Described as an “intricate 3D puzzle” by the team, the structure can be disassembled and put back together while still maintaining its stability.

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Slideshow

The Armadillo Vault's hundreds of limestone slabs are held together without glue

ETH Zurich Beyond Bending Armadillo Vault Iwan Baan

1 of 8

The ability of the Armadillo Vault to stand strong without any glue is nothing less than an ingenious feat of engineering. ETH Zurich designed the massive structure out of limestone slabs for the Venice Biennale 2016, showing how any material can become architecturally versatile with detailed design and a bit of finesse.

ETH Zurich Beyond Bending Armadillo Vault Iwan Baan

399 limestone slabs were brought together after mapping out the technique on RhinoVAULT, a design plugin licensed by the group.

ETH Zurich Beyond Bending Armadillo Vault Iwan Baan

4 of 8

Philippe Block and Tom Van Mele of the research group said, "Without any glue or mortar, with perfectly dry connections, this is really a milestone for stone engineering.”

ETH Zurich Beyond Bending Armadillo Vault Iwan Baan

5 of 8

The Armadillo Vault spans 16 meters (about 20 feet), yet some sections are only as thick as five centimeters. Proportionally, the structure is half the thickness of an eggshell and remarkably strong.

ETH Zurich Beyond Bending Armadillo Vault Iwan Baan

6 of 8

Each slab of limestone was left unfinished on the bottom side for time’s sake, creating an exterior resembling an armadillo shell and an underbelly of textured stripes.

ETH Zurich Beyond Bending Armadillo Vault Iwan Baan

7 of 8

The intentional choice of often-finicky limestone demonstrates how the “relationship between geometry and forces” can be achieved with precision and respect for the materials.

ETH Zurich Beyond Bending Armadillo Vault Iwan Baan

8 of 8

Once the Venice Biennale ends the Armadillo Vault will be moved to a different location. Described as an “intricate 3D puzzle” by the team, the structure can be disassembled and put back together while still maintaining its stability.